causing a voltage sag with duration of more than 1 cycle occurs within the area of vulnerability. However, faults outside this area will not cause the voltage to drop below 0.5 pu. The same discussion applies to the area of vulnerability for ASD loads. The less sensitive the equip- ment, the smaller the area of vulnerability will be (and the fewer times sags will cause the equipment to misoperate). 3.2.3 Transmission system sag performance evaluation The voltage sag performance for a given customer facility will depend on whether the customer is supplied from the transmission system or from the distribution system. For a customer supplied from the transmission system, the voltage sag performance will depend on only the transmission system fault performance. On the other hand, for a customer supplied from the distribution system, the voltage sag performance will depend on the fault performance on both the transmission and distribution systems. This section discusses procedures to estimate the transmission sys- tem contribution to the overall voltage sag performance at a facility. Section 3.2.4 focuses on the distribution system contribution to the overall voltage sag performance. Transmission line faults and the subsequent opening of the protec- tive devices rarely cause an interruption for any customer because of the interconnected nature of most modern-day transmission networks. These faults do, however, cause voltage sags. Depending on the equip- ment sensitivity, the unit may trip off, resulting in substantial mone- tary losses. The ability to estimate the expected voltage sags at an end-user location is therefore very important. Most utilities have detailed short-circuit models of the intercon- nected transmission system available for programs such as ASPEN* One Liner (Fig. 3.7). These programs can calculate the voltage through- out the system resulting from faults around the system. Many of them can also apply faults at locations along the transmission lines to help calculate the area of vulnerability at a specific location. The area of vulnerability describes all the fault locations that can cause equipment to misoperate. The type of fault must also be consid- ered in this analysis. Single-line-to-ground faults will not result in the same voltage sag at the customer equipment as a three-phase fault. The characteristics at the end-use equipment also depend on how the voltages are changed by transformer connections and how the equip- ment is connected, i.e., phase-to-ground or phase-to-phase. Table 3.1 summarizes voltages at the customer transformer secondary for a sin- gle-line-to-ground fault at the primary. Voltage Sags and Interruptions 51 *Advanced Systems for Power Engineering, Inc.; www.aspeninc.com. Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. The relationships in Table 3.1 illustrate the fact that a single-line- to-ground fault on the primary of a delta-wye grounded transformer does not result in zero voltage on any of the phase-to-ground or phase-to-phase voltages on the secondary of the transformer. The magnitude of the lowest secondary voltage depends on how the equipment is connected: ■ Equipment connected line-to-line would experience a minimum volt- age of 33 percent. ■ Equipment connected line-to-neutral would experience a minimum voltage of 58 percent. This illustrates the importance of both transformer connections and the equipment connections in determining the actual voltage that equipment will experience during a fault on the supply system. Math Bollen 16 developed the concept of voltage sag “types” to describe the different voltage sag characteristics that can be experienced at the end-user level for different fault conditions and system configurations. The five types that can commonly be experienced are illustrated in Fig. 3.8. These fault types can be used to conveniently summarize the 52 Chapter Three Figure 3.7 Example of modeling the transmission system in a short-circuit program for calculation of the area of vulnerability. Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. Voltage Sags and Interruptions 53 0.58 1.00 0.58 0.00 1.00 1.00 0.58 1.00 0.58 0.33 0.88 0.88 0.33 0.88 0.88 — — — 0.88 0.88 0.33 0.58 1.00 0.58 TABLE 3.1 Transformer Secondary Voltages with a Single-Line-to-Ground Fault on the Primary Transformer connection Phase-to-phase Phase-to-neutral Phasor (primary/secondary) V ab V bc V ca V an V bn V cn diagram Sag Type D One-phase sag, phase shift Sag Type B One-phase sag, no phase shift Phase Shift Angle None Sag Type C Two-phase sag, phase shift Sag Type E Two-phase sag, no phase shift Sag Type A Three-phase sag Note: Three-phase sags should lead to relatively balanced conditions; therefore, sag type A is a sufficient characterization for all three-phase sags. Number of Phases 12 3 Figure 3.8 Voltage sag types at end-use equipment that result from different types of faults and transformer connections. Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. expected performance at a customer location for different types of faults on the supply system. Table 3.2 is an example of an area of vulnerability listing giving all the fault locations that can result in voltage sags below 80 percent at the cus- tomer equipment (in this case a customer with equipment connected line-to-line and supplied through one delta-wye transformer from the transmission system Tennessee 132-kV bus). The actual expected per- formance is then determined by combining the area of vulnerability with the expected number of faults within this area of vulnerability. The fault performance is usually described in terms of faults per 100 miles/year (mi/yr). Most utilities maintain statistics of fault perfor- mance at all the different transmission voltages. These systemwide statistics can be used along with the area of vulnerability to estimate the actual expected voltage sag performance. Figure 3.9 gives an exam- ple of this type of analysis. The figure shows the expected number of voltage sags per year at the customer equipment due to transmission system faults. The performance is broken down into the different sag types because the equipment sensitivity may be different for sags that affect all three phases versus sags that only affect one or two phases. 3.2.4 Utility distribution system sag performance evaluation Customers that are supplied at distribution voltage levels are impacted by faults on both the transmission system and the distribution system. The analysis at the distribution level must also include momentary interruptions caused by the operation of protective devices to clear the faults. 7 These interruptions will most likely trip out sensitive equip- ment. The example presented in this section illustrates data require- ments and computation procedures for evaluating the expected voltage sag and momentary interruption performance. The overall voltage sag performance at an end-user facility is the total of the expected voltage sag performance from the transmission and distribution systems. Figure 3.10 shows a typical distribution system with multiple feed- ers and fused branches, and protective devices. The utility protection scheme plays an important role in the voltage sag and momentary interruption performance. The critical information needed to compute voltage sag performance can be summarized as follows: ■ Number of feeders supplied from the substation. ■ Average feeder length. ■ Average feeder reactance. ■ Short-circuit equivalent reactance at the substation. 54 Chapter Three Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. Voltage Sags and Interruptions 55 TABLE 3.2 Calculating Expected Sag Performance at a Specific Customer Site for a Given Voltage Level Voltage at Bus monitored Fault type Faulted bus voltage bus (pu) Sag type 3LG Tennessee 132 0 A 3LG Nevada 132 0.23 A 3LG Texas 132 0.33 A 2LG Tennessee 132 0.38 C 2LG Nevada 132 0.41 C 3LG Claytor 132 0.42 A 1LG Tennessee 132 0.45 D 2LG Texas 132 0.48 C 3LG Glen Lyn 132 0.48 A 3LG Reusens 132 0.5 A 1LG Nevada 132 0.5 D L-L Tennessee 132 0.5 C 2LG Claytor 132 0.52 C L-L Nevada 132 0.52 C L-L Texas 132 0.55 C 2LG Glen Lyn 132 0.57 C L-L Claytor 132 0.59 C 3LG Arizona 132 0.59 A 2LG Reusens 132 0.59 C 1LG Texas 132 0.6 D L-L Glen Lyn 132 0.63 C 1LG Claytor 132 0.63 D L-L Reusens 132 0.65 C 3LG Ohio 132 0.65 A 1LG Glen Lyn 132 0.67 D 1LG Reusens 132 0.67 D 2LG Arizona 132 0.67 C 2LG Ohio 132 0.7 C L-L Arizona 132 0.7 C 3LG Fieldale 132 0.72 A L-L Ohio 132 0.73 C 2LG Fieldale 132 0.76 C 3LG New Hampshire 33 0.76 A 1LG Ohio 132 0.77 D 3LG Vermont 33 0.77 A L-L Fieldale 132 0.78 C 1LG Arizona 132 0.78 D 2LG Vermont 33 0.79 C L-L Vermont 33 0.79 C 3LG Minnesota 33 0.8 A Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. 56 Chapter Three FEEDERS 1 2 3 4 SYSTEM SOURCE SUBSTATION FUSED LATERAL BRANCH LINE RECLOSER RECLOSING BREAKERS Figure 3.9 Estimated voltage sag performance at customer equipment due to transmis- sion system faults. Figure 3.10 Typical distribution system illustrating protection devices. Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. ■ Feeder reactors, if any. ■ Average feeder fault performance which includes three-phase-line- to-ground (3LG) faults and single-line-to-ground (SLG) faults in faults per mile per month. The feeder performance data may be avail- able from protection logs. However, data for faults that are cleared by downline fuses or downline protective devices may be difficult to obtain and this information may have to be estimated. There are two possible locations for faults on the distribution systems, i.e., on the same feeder and on parallel feeders. An area of vulnerabil- ity defining the total circuit miles of fault exposures that can cause voltage sags below equipment sag ride-through capability at a specific customer needs to be defined. The computation of the expected voltage sag performance can be performed as follows: Faults on parallel feeders. Voltage experienced at the end-user facility following a fault on parallel feeders can be estimated by calculating the expected voltage magnitude at the substation. The voltage magnitude at the substation is impacted by the fault impedance and location, the configuration of the power system, and the system protection scheme. Figure 3.11 illustrates the effect of the distance between the substation and the fault locations for 3LG and SLG faults on a radial distribution system. The SLG fault curve shows the A-B phase bus voltage on the secondary of a delta-wye–grounded step-down transformer, with an A phase-to-ground fault on the primary. The actual voltage at the end- user location can be computed by converting the substation voltage using Table 3.1. The voltage sag performance for a specific sensitive equipment having the minimum ride-through voltage of v s can be com- puted as follows: E parallel (v s ) ϭ N 1 ϫ E p1 ϩ N 3 ϫ E p3 where N 1 and N 3 are the fault performance data for SLG and 3LG faults in faults per miles per month, and E p1 and E p3 are the total cir- cuit miles of exposure to SLG and 3LG faults on parallel feeders that result in voltage sags below the minimum ride-through voltage v s at the end-user location. Faults on the same feeder. In this step the expected voltage sag magni- tude at the end-user location is computed as a function of fault location on the same feeder. Note that, however, the computation is performed only for fault locations that will result in a sag but will not result in a momentary interruption, which will be computed separately. Examples of such fault locations include faults beyond a downline recloser or a Voltage Sags and Interruptions 57 Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. branched fuse that is coordinated to clear before the substation recloser. The voltage sag performance for specific sensitive equipment with ride-through voltage v s is computed as follows: E same (v s ) ϭ N 1 ϫ E s1 ϩ N 3 ϫ E s3 where E s1 and E s3 are the total circuit miles of exposure to SLG and 3LG on the same feeders that result in voltage sags below v s at the end-user location. The total expected voltage sag performance for the minimum ride- through voltage v s would be the sum of expected voltage sag perfor- mance on the parallel and the same feeders, i.e., E parallel (v s ) ϩ E same (v s ). The total expected sag performance can be computed for other voltage thresholds, which then can be plotted to produce a plot similar to ones in Fig. 3.9. The expected interruption performance at the specified location can be determined by the length of exposure that will cause a breaker or other protective device in series with the customer facility to operate. For example, if the protection is designed to operate the substation breaker for any fault on the feeder, then this length is the total expo- sure length. The expected number of interruptions can be computed as follows: E int ϭ L int ϫ (N 1 ϩ N 3 ) where L int is the total circuit miles of exposure to SLG and 3LG that results in interruptions at an end-user facility. 58 Chapter Three 40 30 20 10 0 50 60 70 80 90 Single-Line-to-Ground Fault 3-Phase Fault % Bus Voltage Phase A-B Distance from Substation to Fault (ft) 0 2500 5000 7500 10000 12500 1500 0 Figure 3.11 Example of voltage sag magnitude at an end-user location as a function of the fault location along a parallel feeder circuit. Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. 3.3 Fundamental Principles of Protection Several things can be done by the utility, end user, and equipment man- ufacturer to reduce the number and severity of voltage sags and to reduce the sensitivity of equipment to voltage sags. Figure 3.12 illus- trates voltage sag solution alternatives and their relative costs. As this chart indicates, it is generally less costly to tackle the problem at its lowest level, close to the load. The best answer is to incorporate ride- through capability into the equipment specifications themselves. This essentially means keeping problem equipment out of the plant, or at least identifying ahead of time power conditioning requirements. Several ideas, outlined here, could easily be incorporated into any com- pany’s equipment procurement specifications to help alleviate prob- lems associated with voltage sags: 1. Equipment manufacturers should have voltage sag ride-through capa- bility curves (similar to the ones shown previously) available to their customers so that an initial evaluation of the equipment can be per- formed. Customers should begin to demand that these types of curves be made available so that they can properly evaluate equipment. 2. The company procuring new equipment should establish a proce- dure that rates the importance of the equipment. If the equipment is critical in nature, the company must make sure that adequate Voltage Sags and Interruptions 59 3 - Overall Protection Inside Plant CONTROLS MOTORS OTHER LOADS Sensitive Process Machine 3 2 1 2 - Controls Protection 1 - Equipment Specifications Utility Source 4 4 - Utility Solutions Feeder or Group of Machines INCREASING COST Customer Solutions Figure 3.12 Approaches for voltage sag ride-through. Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. ride-through capability is included when the equipment is pur- chased. If the equipment is not important or does not cause major disruptions in manufacturing or jeopardize plant and personnel safety, voltage sag protection may not be justified. 3. Equipment should at least be able to ride through voltage sags with a minimum voltage of 70 percent (ITI curve). The relative probabil- ity of experiencing a voltage sag to 70 percent or less of nominal is much less than experiencing a sag to 90 percent or less of nominal. A more ideal ride-through capability for short-duration voltage sags would be 50 percent, as specified by the semiconductor industry in Standard SEMI F-47. 17 As we entertain solutions at higher levels of available power, the solutions generally become more costly. If the required ride-through cannot be obtained at the specification stage, it may be possible to apply an uninterruptible power supply (UPS) system or some other type of power conditioning to the machine control. This is applicable when the machines themselves can withstand the sag or interruption, but the controls would automatically shut them down. At level 3 in Fig. 3.12, some sort of backup power supply with the capability to support the load for a brief period is required. Level 4 rep- resents alterations made to the utility power system to significantly reduce the number of sags and interruptions. 3.4 Solutions at the End-User Level Solutions to improve the reliability and performance of a process or facility can be applied at many different levels. The different technolo- gies available should be evaluated based on the specific requirements of the process to determine the optimum solution for improving the overall voltage sag performance. As illustrated in Fig. 3.12, the solu- tions can be discussed at the following different levels of application: 1. Protection for small loads [e.g., less than 5 kilovoltamperes (kVA)]. This usually involves protection for equipment controls or small, individual machines. Many times, these are single-phase loads that need to be protected. 2. Protection for individual equipment or groups of equipment up to about 300 kVA. This usually represents applying power condition- ing technologies within the facility for protection of critical equip- ment that can be grouped together conveniently. Since usually not all the loads in a facility need protection, this can be a very econom- ical method of dealing with the critical loads, especially if the need for protection of these loads is addressed at the facility design stage. 60 Chapter Three Voltage Sags and Interruptions Downloaded from Digital Engineering Library @ McGraw-Hill (www.digitalengineeringlibrary.com) Copyright © 2004 The McGraw-Hill Companies. All rights reserved. Any use is subject to the Terms of Use as given at the website. [...]... sensitive to voltage sags These include dynamic voltage restorers (DVRs) and UPS systems that use technology similar to the systems described previously but applied at the medium-voltage level 1 Voltage (per unit) 0.5 0 –0.5 Grid voltage Load voltage –1 0.06 Figure 3 .27 0.08 0.1 0. 12 0.14 0.16 0.18 Time (ms) 0 .2 0 .22 0 .24 0 .26 SMES-based system providing ride-through during voltage sag event Downloaded... The incoming ac power is rectified into dc power, which charges a bank of batteries This dc power is then inverted back into ac power, to feed the load If the incoming ac power fails, the inverter is fed from the batteries and continues to supply the load In addition to providing ride-through for power outages, an on-line UPS provides very high isolation of the critical load from all power line disturbances... sags and interruptions on the power system The concept is very simple, as illustrated in Fig 3 .24 A motor powered by the line drives a generator that powers the load Flywheels on the same shaft provide greater inertia to increase ride-through time When the line suffers a disturbance, the inertia of the machines and the flywheels maintains the power supply for several seconds This arrangement may also... UPS A standby power supply (Fig 3 .22 ) is sometimes termed off-line UPS since the normal line power is used to power the equipment until a disturbance is detected and a switch transfers the load to the batterybacked inverter The transfer time from the normal source to the battery-backed inverter is important The CBEMA curve shows that 8 ms is the lower limit on interruption through for power- conscious... supply to a backup supply in seconds Fast transfer switches that use vacuum breaker technology are available that can transfer in about 2 electrical cycles This can be fast enough to protect many sensitive loads Static switches use power electronic switches to accomplish the transfer within about a quarter of an electrical cycle The transfer switch configuration is shown in Fig 3 .28 An example medium-voltage... motor, so the 50 percent tap will deliver only 25 percent of the full-voltage starting current and torque The lowest tap which will supply the required starting torque is selected QC_LD2 Phase A-B Voltage RMS Variation PQNode Local Trigger 115 Duration 110 2. 800 s Min 105 Voltage (%) 80.55 100 Ave 95 88.13 90 Max 1 02. 5 85 80 0 0.5 1 1.5 2 Time (s) Figure 3.31 2. 5 3 3.5 BMI/Electrotek Typical motor-starting... on the medium-voltage systems (2 MVA and larger) Figure 3.19 is an example of a small single-phase compensator that can be used to provide ride-through support for single-phase loads A one-line diagram illustrating the power electronics that are used to achieve the compensation is shown in Fig 3 .20 When a disturbance to the input voltage is detected, a fast switch opens and the power is supplied through... introduces losses and cost 3.4.8 Flywheel energy storage systems Motor-generator sets are only one means to exploit the energy stored in flywheels A modern flywheel energy system uses high-speed flywheels and power electronics to achieve sag and interruption ride-through from 10 s to 2 min Figure 3 .25 shows an example of a flywheel used in energy storage systems While M-G sets typically operate in the open... (www.digitalengineeringlibrary.com) Copyright © 20 04 The McGraw-Hill Companies All rights reserved Any use is subject to the Terms of Use as given at the website Voltage Sags and Interruptions Voltage Sags and Interruptions 73 Example of a static transfer switch application at medium voltage Figure 3 .29 1 Characterize the system power quality performance 2 Estimate the costs associated with the power quality variations... (www.digitalengineeringlibrary.com) Copyright © 20 04 The McGraw-Hill Companies All rights reserved Any use is subject to the Terms of Use as given at the website Voltage Sags and Interruptions 70 Chapter Three The SMES-based system has several advantages over battery-based UPS systems: 1 SMES-based systems have a much smaller footprint than batteries for the same energy storage and power delivery capability.13 2 The stored energy . Tennessee 1 32 0 A 3LG Nevada 1 32 0 .23 A 3LG Texas 1 32 0.33 A 2LG Tennessee 1 32 0.38 C 2LG Nevada 1 32 0.41 C 3LG Claytor 1 32 0. 42 A 1LG Tennessee 1 32 0.45 D 2LG Texas 1 32 0.48 C 3LG Glen Lyn 1 32 0.48. 1 32 0.5 A 1LG Nevada 1 32 0.5 D L-L Tennessee 1 32 0.5 C 2LG Claytor 1 32 0. 52 C L-L Nevada 1 32 0. 52 C L-L Texas 1 32 0.55 C 2LG Glen Lyn 1 32 0.57 C L-L Claytor 1 32 0.59 C 3LG Arizona 1 32 0.59 A 2LG. 1 32 0.59 C 1LG Texas 1 32 0.6 D L-L Glen Lyn 1 32 0.63 C 1LG Claytor 1 32 0.63 D L-L Reusens 1 32 0.65 C 3LG Ohio 1 32 0.65 A 1LG Glen Lyn 1 32 0.67 D 1LG Reusens 1 32 0.67 D 2LG Arizona 1 32 0.67 C 2LG